US2105733A - Chlorination process - Google Patents

Chlorination process Download PDF

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US2105733A
US2105733A US25632A US2563235A US2105733A US 2105733 A US2105733 A US 2105733A US 25632 A US25632 A US 25632A US 2563235 A US2563235 A US 2563235A US 2105733 A US2105733 A US 2105733A
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chlorinated
chlorine
chlorination
pressure
atmospheres
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Henry B Hass
Earl T Mcbee
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Purdue Research Foundation
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    • CCHEMISTRY; METALLURGY
    • C07ORGANIC CHEMISTRY
    • C07CACYCLIC OR CARBOCYCLIC COMPOUNDS
    • C07C17/00Preparation of halogenated hydrocarbons
    • C07C17/093Preparation of halogenated hydrocarbons by replacement by halogens
    • C07C17/10Preparation of halogenated hydrocarbons by replacement by halogens of hydrogen atoms

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  • Prior Process 1 The hydrocarbon vapor is mixed with chlorine, and the mixture is heated to effect chlorination, either in the presence cor absence of catalysts, at or near atmospheric pressure. For instance, see the Ayres Patent No. 1,717,136.
  • Prior Process 2 The hydrocarbon vapor is preheated to reaction temperature, and chlorine is injected at high velocity to efiect chlorination. See our Patent No. 2,004,072, granted June 4, 1935.
  • Prior Process 3 The hydrocarbon, either in liquid phase or in vapor phase, is treated with chlorine in the presence of light, either at or near atmospheric pressure.
  • Prior Process 4 A catalyst, for example iodine, is dissolved in a higher liquid hydrocarbon, for example hexane, in liquid phase at or near atmospheric pressure; and the hydrocarbon with chlorine to efiect the chlorination.
  • a catalyst for example iodine
  • a higher liquid hydrocarbon for example hexane
  • Prior Process 5 A mixture of a saturated hydrocarbon with a small amount of an olefine, is treated with chlorine at or near atmospheric pressure. The presence of the olefine accelerates the substitutive chlorination of the co-present saturated hydrocarbon.
  • Prior Process 6 Hydrocarbons of high molecular weight, having at least 17 carbon atoms, have 4:) been chlorinated in liquid phase at substantially atmospheric pressure and elevated temperature.
  • the chlorination can be at lower temperature, and in liquidphase operation no vaporization precedes the chlorination, the heat requirement of the reaction is greatly reduced as compared to vapor-phasechlorination at high temperature at normal pressure.
  • temperature control is facilitated by having the higher concentration, whether in liquid phase or in vapor phase under compression, since heat transfer between the solid walls of the chlorinator and its contents is better than it is between such solid walls and a gas at or near atmospheric pressure.
  • an excess of the liquid hydrocarbon to be chlorinated (for example, methane, ethane, propane hexadecane among the parafllns, and cyclohexane and decalin among the naphthenes, with a suitable inert diluent such as carbon tetrachloride to maintain liquidity in the case of the more. volatile hydrocarbons) is pumped from a hydrocarbon-storage tank II by a pump I2 to a suitable mixing pipe l3 into which liquid chlorine is also pumped from the chlorine-storage tank I! by a. pump I5.
  • a suitable inert diluent such as carbon tetrachloride
  • Regulating valves l8 and i9 are provided at the outlets of the reactor i6 and cooler "to control the pressures within the reactor and the cooler respectively, and to make possible high temperatures in the reactor while maintaining the liquid phase. If temperatures are desired above the critical temperature of thematerialto be chlorinated, as we find advantageous in oertain cases, an inert diluent such as carbon tetrachloride may be used, and it is in that case that such diluent is separated from the unrecycled reaction products and recycled with the unreacted hydrocarbon and any chlorides of which it is desired to obtain further chlorination.
  • an inert diluent such as carbon tetrachloride
  • the mixing pipe l3 may be put within the reactor ii if desired, with separate leading-in pipes which of chlorine to about ten mols of pentane.
  • reactor to that the hydrocarbon with its inert diluent and the chlorine may be separately heated before being mixed; in the same general manner as is shown for vapor-phase,
  • Example 1 Carbon tetrachloride, saturated with methane at a pressure of five atmospheres, is placed in the hydrocarbon-storage tank 'I I, and the pumps I2 and I5 and the valves are so operated thatin the mixing pipe l3 mixing is obtained of between three and four mols of chlorine for each moi. of methane.
  • the resultant solution of methane and chlorine in carbon tetrachloride is heated to about 240 to 250 C. in the reactor, which in this case is desirably a nickel tube immersed in a molten mixture of potassium nitrate and sodium nitrite in eutectic proportions.
  • the rate at which the solution is pumped through the reactor is regulated by testing the effluent chlorinated product for free chlorine, and is controlled so thatiittle or no chlorine escapes reaction. A pressure is maintained in the reactor of about 70 atmospheres.
  • the chlorinated product obtained is principally carbon tetrachloride containing some chloroform. In this case carbon tetrachloride is both the inert diluent and one of the principal final products.
  • Example 2 Propane dissolved in a quantity of carbon tetrachloride is placed in the hydrocarbon-storage tank II, and the pumps and valves are so operated that one mol. of chlorine is mixed with from five to ten mols of dissolved propane; and the solution is chlorinated as in Example 1. With these proportions, the principal product obtained on the passage through the reactor is 1- chloropropane. This may be recycled to obtain more highly chlorinated products, chief among which are 1,2-dichloropropane and 1.3-dichloropropane. For this chlorination we prefer a temperature of about 200 0., at a pressure of about 40 to 50 atmospheres.
  • the operation is conducted as in Examples 1 and 2.
  • Example 4 A kerosene fraction having a distillation range of 200 to 250 C., which indicates that the fraction is largely a mixture of hydrocarbons having from 11 to 16 carbon atoms, is placed in the hydrocarbon storage tank II, and the pumps and valves are operated so that a mixture is produced in the mixing pipe l3 of about 1 mol. of chlorine to 5 mols of hydrocarbons. The operation is then conducted as in Examples 1 and 2.
  • the process oi substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the paraflin and naphthene series and their partially chlorinated derivatives, which consists in injecting chlorine and the material to. be chlorinated under elevated pressure into a mixing tube, passing the mixture into a reactor maintained at a temperature sufliciently elevated to cause between the chlorine and the material to be chlorinated a chlorination reaction which is at least '90% complete within one minute in the'absence of light and a catalyst, controlling the pressure in said reactor to maintain it above ten atmospheres, separating the desired chlorinated product from the material which still requires substitutive chlorinationto produce the desired HENRY B. BASS. EARL T. MCBEE.

Description

H. B. HASS ET AL CHLORINATION PROCESS Filed Jpme 8, 1935 m mwoxoww zo semi Patented Jan. 18, 1938 UNITED STATES PATENT OFFICE CHLORINATION PROCESS Henry B. Bass and Earl '1'. McBee, West Laiayette, Ind, assignors to Purdue Research Foundation, West Lafayette, Ind., a corporation oi Indiana Application June 8, 1935, Serial No. 25,632
13 Claims.
5 those of not to exceed 16 carbon atoms, and their partially chlorinated derivatives.
Considerable work has already been done in the chlorination'of compounds of this generaltype. Among the" general procedures which have been used are the following:
Prior Process 1: The hydrocarbon vapor is mixed with chlorine, and the mixture is heated to effect chlorination, either in the presence cor absence of catalysts, at or near atmospheric pressure. For instance, see the Ayres Patent No. 1,717,136.
Prior Process 2: The hydrocarbon vapor is preheated to reaction temperature, and chlorine is injected at high velocity to efiect chlorination. See our Patent No. 2,004,072, granted June 4, 1935.
Prior Process 3: The hydrocarbon, either in liquid phase or in vapor phase, is treated with chlorine in the presence of light, either at or near atmospheric pressure.
Prior Process 4: A catalyst, for example iodine, is dissolved in a higher liquid hydrocarbon, for example hexane, in liquid phase at or near atmospheric pressure; and the hydrocarbon with chlorine to efiect the chlorination.
Prior Process 5: A mixture of a saturated hydrocarbon with a small amount of an olefine, is treated with chlorine at or near atmospheric pressure. The presence of the olefine accelerates the substitutive chlorination of the co-present saturated hydrocarbon.
Prior Process 6: Hydrocarbons of high molecular weight, having at least 17 carbon atoms, have 4:) been chlorinated in liquid phase at substantially atmospheric pressure and elevated temperature.
Our chlorination process difiers from these prior processes in that it is carried out under high pressure, of at least ten atmospheres, with the 45 material to be chlorinated either in liquid phase or in a highly compressed vapor phase. If desired, it can be carried out in the absence of both light and a catalyst; and we prefer that course. By the use of high pressure, we are able to get 50 a number of advantages.
With some hydrocarbons we are able to main- 55 temperature which we use, whether the material such catalyst dissolved in it is heated with to be chlorinated is in liquid phase or in vapor phase, is sufllciently high so that it is capable of causing rapid reaction between chlorine and such material in the absence of light and a catalyst-by which we mean, as pointed out in our aforesaid Patent No. 2,004,072, a chlorination reaction that is at least 90% complete within one minute.
By reason oi the pressure we are able to in crease the concentration, relative as well as absolute, of materials to be chlorinated that exist in vapor phase at normal or near-normal pres- 7 sure.
In addition, we are able to increase the absolute concentration of chlorine whether the material to be chlorinated is in the liquid phase (Henry's law) or in the vapor phase; and in this way we are able to get an increased velocity of reaction, limited only by the increased violence of the reaction at higher chlorine concentrations, and in consequence to decrease the time of exposure to pyrolytic conditions.
Further, the high pressure creates a tendency to push to the left the reversible reaction of which the following equation is an example:
Our process also makes it unnecessary to use fragile material such as transparent glass or silica, such as are necessary when the reaction is accelerated by light.
In certain prior thermal processes, pyrolysis causes frequent shut-downs, made necessary to remove accumulations of carbonaceous deposits in the chlorination tubes. We can substantially completely avoid these shut-downsindeed, we can oftendo so completely in liquid-phase opera: tion.
In addition, by increasing the temperature of the material to be chlorinated in high concentration, either in liquid phase or in vapor phase under high pressure, we are able to increase the proportion of primary chlorination to secondary and/or tertiary chlorination.
This increase in the proportion of primary chlorides, and the consequent decrease in the proportions of secondary and/or tertiary chlorides, is produced by raising the temperature of chlorination even in vapor-phase chlorination at normal pressure, as is pointed. out in our aforesaid Patent No. 2,004,072;'but the efiect is more pronounced when the material to be chlorinated is in liquid phase. In consequence, greater yields of the primary chlorides, which are usually more desirable than the isomeric secondary or tertiary chlorides, can be obtained at lower temperatures in liquid phase under high pressure than in vapor phase at normal pressure.
Further, because the chlorination can be at lower temperature, and in liquidphase operation no vaporization precedes the chlorination, the heat requirement of the reaction is greatly reduced as compared to vapor-phasechlorination at high temperature at normal pressure.
In addition, temperature control is facilitated by having the higher concentration, whether in liquid phase or in vapor phase under compression, since heat transfer between the solid walls of the chlorinator and its contents is better than it is between such solid walls and a gas at or near atmospheric pressure.
However, ,thereare'two disadvantages to our process.
First, the explosive; limits of hydrocarbonchlorine mixtures are wider at'high concentration, whether in liquid phase or in vapor phase under compression, than at low concentration, such as in vapor phase at normal pressure; so that more care must be used to avoid explosions. In consequence, although the absolute concentration of chlorine is increased, it is necessary (unless an inert liquid diluent is ,used as hereinafter set forth) to have a larger excess of the material to be chlorinated over the chlorine used than is necessary in vapor-phase chlorination at atmospheric pressure. But this is not a serious disadvantage, for it is almost always desirable for other reasons to use a large excess of the material to be chlorinated; for example, in order to diminish the over-chlorination of such material.
Second, special pumps are required,'that are suitable forpumping liquid chlorine and liquid hydrocarbon under pressureto the chlorinator; but such pumps are available.
These two difiiculties are thus relatively minor, and, especially in the case of the lower hydrocarbons, may even be lessened by the use of an 1 inert liquid diluent, such as carbon tetrachloride,
which not only maintains liquidity but also permits greater relative concentrations of chlorine to be used without danger of explosion.
The use of an inert liquid diluent in which both chlorine and the material to be chlorinated are freely soluble is especially advantageous in the '1 sure to maintain the mixture at least largely in liquid phase. The vapor pressure of carbon tetrachloride at 200 C. is approximately 14.4 atmospheres, so that a pressure at least as great as that should be employed in thischlorination of methane at this temperature. However, the
exact pressure required naturally depends upon the concentration of the reactants in the carbon tetrachloride and varies with that concentration; After the chlorination, the inert liquid diluent is usually removed, as by rectification, so that it may be re-used. According to our invention, pressures 'are used in excess of ten atmospheres. There may be a very considerable excess in pressure above tenatmospheres, for we have found no upper limit of pressure save that action at atmospheric pressure, and we thus lessen the effects of pyrolysis. By rapid reaction, as already stated, we mean a chlorination reaction which is at least 90% complete within one minute in the absence of light and of a chlorination catalyst.
A suitable apparatus for carrying out our process is shown in the accompanying drawing, of which the single figure is a diagrammatic representation of such an apparatus.
In such apparatus, an excess of the liquid hydrocarbon to be chlorinated (for example, methane, ethane, propane hexadecane among the parafllns, and cyclohexane and decalin among the naphthenes, with a suitable inert diluent such as carbon tetrachloride to maintain liquidity in the case of the more. volatile hydrocarbons) is pumped from a hydrocarbon-storage tank II by a pump I2 to a suitable mixing pipe l3 into which liquid chlorine is also pumped from the chlorine-storage tank I! by a. pump I5. I From the mixing-pipe i 3 the liquid mixture of chlorine with an excess of hydrocarbon, and with the inert diluent if it isused, flows through a reactor, where it is heated to cause reaction, to a cooler l1; and thence to suitable separating apparatus, such for instance as that shown in our aforesaid Patent No. 2,004,072, so that the unreacted hydrocarbon, with the inert diluent if present, may be returned by the pipe and recycled. If desired, any of the chlorides obtained may also be recycled, such for instance as mono-chlorides if it is desired to obtain dichlorides. No heat-exchange mechanism is essential between the outflow fluids and the in-fiow fluids, although neither is it essential that there be none.
Regulating valves l8 and i9 are provided at the outlets of the reactor i6 and cooler "to control the pressures within the reactor and the cooler respectively, and to make possible high temperatures in the reactor while maintaining the liquid phase. If temperatures are desired above the critical temperature of thematerialto be chlorinated, as we find advantageous in oertain cases, an inert diluent such as carbon tetrachloride may be used, and it is in that case that such diluent is separated from the unrecycled reaction products and recycled with the unreacted hydrocarbon and any chlorides of which it is desired to obtain further chlorination. In case the inert diluent is not used, and the temperatures are such that the material to be chlorinated is above the criticaltemperature and hence in vapor phase, our app ratus is nevertheless suitable and efl'ective, because of the high concentration which is obtained by reason of the high pressure used.
We prefer at present, although it is not essential to our invention, to operate with the reactor at temperatures above 100 0., and ordinarily not above 350 C. and frequently not above 250 C.; and with pressures which though above the minimum of 10 atmospheres do not exceed 150 atmospheres.
When carbon tetrachloride is used as an inert diluent to carry the material to be chlorinated. the mixing pipe l3 may be put within the reactor ii if desired, with separate leading-in pipes which of chlorine to about ten mols of pentane.
iii)
are also in that reactor, to that the hydrocarbon with its inert diluent and the chlorine may be separately heated before being mixed; in the same general manner as is shown for vapor-phase,
chlorination in our aforesaid Patent No. 2,004,072. The following are examples of chlorination by our process:
Example 1 Carbon tetrachloride, saturated with methane at a pressure of five atmospheres, is placed in the hydrocarbon-storage tank 'I I, and the pumps I2 and I5 and the valves are so operated thatin the mixing pipe l3 mixing is obtained of between three and four mols of chlorine for each moi. of methane. The resultant solution of methane and chlorine in carbon tetrachloride is heated to about 240 to 250 C. in the reactor, which in this case is desirably a nickel tube immersed in a molten mixture of potassium nitrate and sodium nitrite in eutectic proportions. The rate at which the solution is pumped through the reactor is regulated by testing the effluent chlorinated product for free chlorine, and is controlled so thatiittle or no chlorine escapes reaction. A pressure is maintained in the reactor of about 70 atmospheres. The chlorinated product obtained is principally carbon tetrachloride containing some chloroform. In this case carbon tetrachloride is both the inert diluent and one of the principal final products.
Example 2 Propane dissolved in a quantity of carbon tetrachloride is placed in the hydrocarbon-storage tank II, and the pumps and valves are so operated that one mol. of chlorine is mixed with from five to ten mols of dissolved propane; and the solution is chlorinated as in Example 1. With these proportions, the principal product obtained on the passage through the reactor is 1- chloropropane. This may be recycled to obtain more highly chlorinated products, chief among which are 1,2-dichloropropane and 1.3-dichloropropane. For this chlorination we prefer a temperature of about 200 0., at a pressure of about 40 to 50 atmospheres.
Example. 3
A liquid pentane, dissolved if desired in carbon tetrachloride (although that is not necessary), is placed in the hydrocarbon-storage tank II, and the pumps and valves are operated so that a mixture is produced in the mixing pipe l3 of one mol. The operation is conducted as in Examples 1 and 2.
Example 4 A kerosene fraction having a distillation range of 200 to 250 C., which indicates that the fraction is largely a mixture of hydrocarbons having from 11 to 16 carbon atoms, is placed in the hydrocarbon storage tank II, and the pumps and valves are operated so that a mixture is produced in the mixing pipe l3 of about 1 mol. of chlorine to 5 mols of hydrocarbons. The operation is then conducted as in Examples 1 and 2.
The above examples are intended to be illustrative only, and arenot given as limitations of our invention beyond the terms of the claims. Such factors as concentrations, pressures (with a minimum of 10 atmospheres), temperatures, nature of hydrocarbon or, chloro-hydrocarbon used as the material to be chlorinated, diluent (if any), material and shape of the chlorinator, etc.,
may be varied without departing from the spirit of our invention.
We claim as our invention:
1. The process of substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the parafiln and naphthene series and their partially chlorinated derivatives, which consists in subjecting a mixture of chlorine and the material to be chlorinated under a pressure in excess of ten atmospheres to a temperature which is capable of causing a reaction between them which is at least complete within one minute in the absence of light and a catalyst.
2. The process of substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the paraffin and naphthene series and their partially chlorinated derivatives, which consists in subjecting a mixture of chlorine and the material to be chlorinated under a pressure in excess of ten atmospheres to a temperature which is capable of causing a reaction between them, which is at least 90% complete within one minute in the absence of light and a catalyst. with the material to be chlorinated in liquid phase.
3. The process of'substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the paramn and naphthene series and their partially chlorinated derivatives, which consists in subjecting a mixture of chlorine and the material to be chlorinated under a pressure in excess of ten atmospheres to a. temperature which is capable of causing a reaction between them which is at least 90% complete within one minute in the absence 0f light and a catalyst, with the material to be chlorinated in vapor phase.
4. The process of substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the parafiin and naphthene series and their partially chlorinated derivatives, which consists insubjecting a mixture of chlorine and the material to be chlorinated under a pressure in excess of ten atmospheres to a temperature which is capable of causing a reaction between them which is at least 90% complete within one minute in the absence of light and a catalyst, with the material to be chlorinated dissolved in an inert liquid diluent.
5. The process of substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the paraffln and naphthene series and their partially chlorinated derivatives, which consists in subjecting a mixture of chlorine and the material to bechlorinated under a pressure in excess of ten atmospheres to a temperature which is capable of causing a reaction between them which is at least 90% complete within one minute in the absence of light and a catalyst, with the material to be chlorinated dissolved in carbon tetrachloride. r
6. The process of substitutively chlorinating in the absence of light and a catalyst, with a large molar excess of the material tcbe chlorinated over the amount of chlorine present.
'7. The process of substitutively chlorinating compounds 01' the class consisting or saturated hydrocarbons of not to exceed sixteen carbon atoms of the paraffin and naphthene series and their partially chlorinated derivatives, which consists in subjecting a mixture of chlorine and the material to be chlorinated under a pressure in excess of ten atmospheres and in the absence of both light and'a catalyst to a temperature which excess of ten atmospheres.
9. The process of substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbonatoms of-the paramn and naphthene series'and their partially chlorinated derivatives, which con sists in subjecting a mixture of chlorine and the material to be chlorinated under a pressure in excess or ten atmospheres to a temperature which is capable of causing a reaction between them which is at least 90% complete within one minute in the absence of light and a catalyst, and separating organic chlorides so produced from co-present material.
1.0. The process of substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the paraflin and naphthene series and their partially chlorinated derivatives, which consists in injecting chlorine and the material to be chlorinated, with thelatter in molar excess, under elevated pressure into a mixing tube, passing the mixture into a reactor maintained at a temperature sufliciently elevated to cause between the chlorine and the material 'to be chlorinated a chlorination reaction which is at least 90% complete within one minute in the absence of light and a catalyst, and controlling the pressure in said reactor to maintain it above ten atmospheres.
11. The process of substitutively ohlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the parail'ln and naphthene series and their partially chlorinated derivatives, which consists in injecting chlorine and the material to be chlorinated under elevated pressure into 'a mixing tube, passing the mixture into a reactor maintained at a temperature sufliciently elevated to cause between the chlorine and'the material to be chlorinated a chlorination reaction which is at least 90% complete within one minute in the absence of light and a catalyst, and controlling the pressure in said reactor to maintain it above ten atmospheres.
12. The process of substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the paraflin and naphthene series and their partially chlorinated derivatives, which consists in injecting chlorine and the material to be chlorinated, with the latter in molar excess, under elevated pressure into a mixing tube, passing the mixture into a reactor'maintained at a temperature sufficiently elevated to cause between the chlorine and the material to be chlorinated a chlorination reaction whiclris at least 90% complete within one minute in the absence of light ,and a catalyst, controlling the pressure in said reactor to maintain it above ten atmospheres, separating the desired chlorinated product from the material which still requires substitutive chlorination to produce the desired chlorinated product, and recycling said material which still requires chlorination. 13. The process oi substitutively chlorinating compounds of the class consisting of saturated hydrocarbons of not to exceed sixteen carbon atoms of the paraflin and naphthene series and their partially chlorinated derivatives, which consists in injecting chlorine and the material to. be chlorinated under elevated pressure into a mixing tube, passing the mixture into a reactor maintained at a temperature sufliciently elevated to cause between the chlorine and the material to be chlorinated a chlorination reaction which is at least '90% complete within one minute in the'absence of light and a catalyst, controlling the pressure in said reactor to maintain it above ten atmospheres, separating the desired chlorinated product from the material which still requires substitutive chlorinationto produce the desired HENRY B. BASS. EARL T. MCBEE.
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Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2499578A (en) * 1945-05-22 1950-03-07 Allied Chem & Dye Corp Method of chlorinating hydrocarbon mixtures
US2541190A (en) * 1944-06-20 1951-02-13 Anthony F Benning Fluorination of lubricating oil
US2558319A (en) * 1947-12-11 1951-06-26 Hooker Electrochemical Co Process for production of chloral and chloral hydrate, and their phenyl condensationproduct
DE906933C (en) * 1942-01-14 1954-03-18 Basf Ag Process for the production of monochlorinated hydrocarbons
US2683688A (en) * 1950-03-06 1954-07-13 Ruhrchemie Ag Preparation of alkyl monochlorides
US2792435A (en) * 1954-04-30 1957-05-14 Diamond Alkali Co Preparation of methyl chloride and methylene chloride
US2883436A (en) * 1955-07-28 1959-04-21 Pure Oil Co Hydrohalogenation of mono halogenated alkanes
US2964509A (en) * 1956-10-16 1960-12-13 Du Pont Process for chlorination of olefine polymers
US3502734A (en) * 1966-05-11 1970-03-24 Du Pont Process for partially chlorinating methyl chloride and/or methylene chloride
JPS5133885B1 (en) * 1971-07-09 1976-09-22

Cited By (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE906933C (en) * 1942-01-14 1954-03-18 Basf Ag Process for the production of monochlorinated hydrocarbons
US2541190A (en) * 1944-06-20 1951-02-13 Anthony F Benning Fluorination of lubricating oil
US2499578A (en) * 1945-05-22 1950-03-07 Allied Chem & Dye Corp Method of chlorinating hydrocarbon mixtures
US2558319A (en) * 1947-12-11 1951-06-26 Hooker Electrochemical Co Process for production of chloral and chloral hydrate, and their phenyl condensationproduct
US2683688A (en) * 1950-03-06 1954-07-13 Ruhrchemie Ag Preparation of alkyl monochlorides
US2792435A (en) * 1954-04-30 1957-05-14 Diamond Alkali Co Preparation of methyl chloride and methylene chloride
US2883436A (en) * 1955-07-28 1959-04-21 Pure Oil Co Hydrohalogenation of mono halogenated alkanes
US2964509A (en) * 1956-10-16 1960-12-13 Du Pont Process for chlorination of olefine polymers
US3502734A (en) * 1966-05-11 1970-03-24 Du Pont Process for partially chlorinating methyl chloride and/or methylene chloride
JPS5133885B1 (en) * 1971-07-09 1976-09-22

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